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In 2022, a cement plant initiated a project to renovate its bucket elevator discharge chutes. They entrusted Nantong Darko Building Materials Machinery Co., Ltd. with the entire process, from production to equipment installation and operation. Darko quickly dispatched technicians to the site for an on-the-spot evaluation. They identified several key issues with the discharge chutes.

Main Issues

1.Insufficient Wear Resistance: The discharge chutes used wear-resistant manganese steel plates, which had poor durability. This led to multiple wear-through points and material leakage. The worn manganese steel plates became uneven, causing material to stick.

 

2.Unreasonable Structural Design: The angle in the middle of the discharge chutes was too steep, failing to effectively cushion the material. As a result, the lower part of the chute experienced severe wear.

 

3.Uneven Design of the Sloped Chute: The design of the sloped section was uneven. Material concentrated on one side, while the other side showed little wear. This uneven force distribution caused severe wear on the side in contact with the material and led to material accumulation.

 

Solutions

To address these issues, Darko's technicians proposed practical solutions:

1.Optimize Overall Structure: They adjusted the angle in the middle of the discharge chutes to reduce the impact force of the material. This modification effectively slows down and cushions the material.


2.Redesign the Sloped Chute: They changed the lower sloped section from an irregular rhomboid shape to a parallelogram. This design distributes the impact force more evenly across the bottom and sides, extending the equipment's lifespan.

 

3.Replace Wear Materials: They substituted wear-resistant ceramic liners for the manganese steel plates. The ceramic liners offer superior wear and corrosion resistance, and their smooth surface reduces material buildup.

Vertical bucket elevator system for lifting bulk materials, highlighting the conveyor mechanism and bucket arrangement

Simulation Testing and Expected Results

Darko's technicians conducted simulation tests using the new solutions. They expect to increase the lifespan of the bucket elevator discharge chutes by 3 to 5 times, improve work efficiency by 3% to 12%, and reduce the likelihood of material blockage by 20% to 30%.

These design optimizations will significantly enhance the performance of the discharge chutes. They will ensure the cement plant's production efficiency and the long-term stability of the equipment. If you are facing similar issues, feel free to contact us. We are ready to provide you with professional solutions.

The stainless steel bag dust collector is an advanced type of bag dust collector, distinguished from traditional iron models by its unique material. Thanks to its excellent corrosion resistance and oxidation resistance, this dust collector performs exceptionally well in many industrial applications. This article explores the working principle, features, and customization considerations of stainless steel bag dust collectors to help you choose the right dust control solution.

 

Working Principle of Stainless Steel Bag Dust Collector

The working process of the stainless steel bag dust collector is simple and efficient. Dust-laden air first enters the hopper or filter bag chamber through the inlet. The air passes through the filter bags, where it is purified before entering the clean air chamber. The clean air then exits through the exhaust port via a fan. As dust accumulates on the filter bag surface, the resistance of the equipment increases. To ensure that the resistance does not exceed 1200Pa, regular dust cleaning is necessary.

 

The cleaning process is automatically controlled by a PLC program. The controller periodically activates the pulse valve, releasing compressed air (0.5-0.7Mpa) through the blowing pipe. This action draws in several times more surrounding air, causing the filter bags to expand rapidly. The reverse airflow helps dislodge the dust from the bags, achieving effective cleaning.

 

Reasons to Choose a Stainless Steel Bag Dust Collector

1. Corrosion and Oxidation Resistance

Stainless steel bag dust collectors are primarily made from 304 and 316 stainless steel plates. These materials ensure stability and durability when handling corrosive gases. In contrast, traditional iron dust collectors cannot meet these demanding application needs.

2. Longer Lifespan

Due to the superior properties of stainless steel, these dust collectors have a significantly longer lifespan than traditional models. This feature reduces the frequency of replacements and maintenance costs.

3. Aesthetic Appeal

The appearance of stainless steel is more attractive, making it suitable for industrial environments where aesthetics matter.

 

The Stainless Steel Bag Dust Collector is placed in an open area, effectively removing dust particles from the air to ensure a cleaner workspace.

Considerations for Customizing a Stainless Steel Bag Dust Collector

When customizing a stainless steel bag dust collector, companies should consider the following aspects:

1. Size and Capacity

Choose the appropriate model and specifications based on the actual conditions of the production site. If space is limited, opt for a compact unit. If dust concentration is high, select a larger capacity collector to ensure effective dust removal.

2. Filter Material

Select filter materials based on the size, chemical properties, and temperature of the dust particles. Common materials include polyester fiber, fiberglass, and PPS.

3. Number of Bags

The number of bags should correspond to the dust concentration and air flow rate at the production site. More bags typically result in better dust removal efficiency.

4. Auxiliary Equipment Configuration

Consider configuring cleaning systems and control systems based on actual needs. A cleaning system can effectively remove dust from the bags, ensuring long-term stable operation. An automated control system can enhance efficiency.

Maintenance and Care

To ensure the long-term stable operation of the stainless steel bag dust collector, companies should pay attention to the following points:

Ensure that the materials and manufacturing processes meet relevant standards for stability and durability.
Design the layout based on the production site conditions to ensure effective and safe operation.
Conduct regular maintenance and replace damaged parts and bags promptly.

Conclusion

The stainless steel bag dust collector is an essential piece of equipment in modern industry due to its efficiency and reliability. With proper customization, companies can obtain dust control solutions that meet their specific needs. Darko can provide you with flexible and efficient dust control equipment to improve the cleanliness of your production environment and protect employee health. If you have any needs or questions, please feel free to contact us. We are dedicated to providing you with professional service and support.

Butterfly valves play a crucial role in controlling the flow of various fluids, including air, water, steam, corrosive substances, slurries, oils, liquid metals, and radioactive materials. Specifically, these valves primarily function as shut-off and throttling devices in piping systems. Notably, a butterfly valve features a disc-shaped plate that rotates around its axis within the valve body, which allows for precise opening and closing of the flow.

Structural Characteristics of Butterfly Valves

Butterfly valves have several notable features:

 

1.Simple Structure: Designed with simplicity in mind, butterfly valves are compact, lightweight, and material-efficient. Furthermore, their small installation size enables quick operation with a 90° rotation, requiring minimal torque. As a result, this design makes them ideal for effective fluid flow control and reliable sealing.

 

2.Efficient Fluid Handling: In addition, these valves handle slurries effectively while minimizing liquid accumulation at the pipeline entrance. Moreover, they excel in sealing at low pressures and provide excellent throttling performance.

 

3.Streamlined Design: Therefore, the aerodynamic shape of the disc reduces fluid resistance, making butterfly valves an energy-efficient choice for fluid control.

 

4.Robust Stem Structure: The through-stem design enhances mechanical properties and corrosion resistance. Furthermore, the stem rotates during operation, preventing any vertical movement that could damage the packing seal. In addition, the stem securely attaches to the disc, ensuring it remains intact in case of failure.

 

5.Versatile Connection Options: Butterfly valves can be connected via flanged, wafer, butt-welded, or lugged connections. Moreover, they can be actuated manually or using various mechanisms, including worm gear, electric, pneumatic, hydraulic, or electro-hydraulic systems, which allows for remote control and automation.

 

Classification of Butterfly Valves

Butterfly valves can be classified based on their actuation methods:

 

1.Electric Butterfly Valves: Electric Butterfly Valves use electric power as the driving force, enabling remote and automated control via electrical signals. They are suitable for applications requiring precise control and long-distance operation. However, their complexity demands regular maintenance of the motor and associated components, and their response time is relatively slow.

 

2.Pneumatic Butterfly Valves: Utilizing compressed air as the power source, pneumatic butterfly valves respond quickly to control signals. They are best suited for applications where high precision is not critical. Their simpler structure requires minimal maintenance, mainly focusing on the condition of the air supply.

 

3.Hydraulic Butterfly Valves: These valves operate using hydraulic oil as the power source, converting hydraulic signals into mechanical force to open or close the valve. They thrive in environments with high temperatures, pressures, and corrosive substances, making them perfect for chemical, metallurgy, and petroleum industries.

 

4.Manual Butterfly Valves: Manual butterfly valves are operated by hand, allowing users to directly control the opening and closing of the disc.

 

A set of three pneumatic butterfly valves featuring red and blue handles, showcasing their distinct operational controls.

Conclusion

Butterfly valves are efficient solutions for fluid control in various applications. Their simple design, effective sealing, and diverse actuation methods make them indispensable in many industries. As a leading brand, Darko is committed to providing high-quality butterfly valve products to meet various customer needs. By understanding the features and classifications of butterfly valves, you can select the right valve for your specific requirements. If you have any questions or need assistance, please feel free to contact us!

The vertical mill serves as a key piece of equipment in cement production. Its operational status directly impacts both the yield and quality of cement products. Rollers and liners are core wear components in the vertical mill. Over time, they experience wear, leading to decreased grinding efficiency, increased energy consumption, and fluctuations in product quality. Therefore, regularly replacing rollers and liners is essential for ensuring smooth operation and enhancing production efficiency. This plan outlines the detailed process for replacing rollers and liners in cement plant vertical mills. It includes key considerations and safety measures to ensure a successful replacement operation.

Two combined scenes of a vertical roller mill, showcasing its operational setup and components in a cement production environment.

I. Project Preparation

1.Material Preparation: First, assess the vertical mill model and its wear condition. Then, procure rollers, liners, and fasteners that meet specification requirements. Also, prepare necessary tools such as lifting equipment, wrenches, and welding tools.

 

2.Downtime Planning: Next, coordinate with the production planning department. Determine the best downtime window to minimize production disruptions. Inform relevant departments to prepare for emergency responses during the downtime.

 

3.Personnel Training: Conduct safety training for all personnel involved in the replacement operation. Ensure everyone is familiar with operating procedures and emergency response measures.

 

4.Site Setup: Clear the area around the vertical mill to provide ample workspace. Set up safety warning signs and isolate non-working areas.

 

II. Replacement Steps

1.Shutdown and Lockout: First, follow the operating procedures to shut down the mill. Disconnect the power supply. Hang a "Do Not Energize" sign. Use locks or mechanical devices to prevent accidental restarts.

 

2.Dismantling Old Components:

  • Use specialized tools to remove the fastening bolts or weld points at both ends of the rollers.
  • Carefully loosen the roller securing device. Use lifting equipment to remove each roller and place them in a designated area.
  • Clean residual materials from the grinding chamber. Inspect and remove old liners, noting their installation positions for reinstallation.

 

3.Inspection and Preparation:

  • Inspect the new rollers and liners for any damage, cracks, or defects.
  • Clean the installation surfaces to remove oil, rust, and other contaminants.

 

4.Installing New Components:

  • Install new liners in their original positions or optimized layouts. Ensure they are flat and securely fastened.
  • Use lifting equipment to install each new roller. Adjust their positions for optimal grinding conditions.
  • Tighten the bolts or weld points at both ends of the rollers to secure the fit.

 

5.Debugging and Inspection:

  • After installation, perform initial debugging. Check for proper installation and any looseness or abnormal noises.
  • Gradually start the vertical mill. Conduct a no-load trial run. Observe its operation and make adjustments to achieve the best working state.

 

III. Safety Considerations

1.Personal Protective Equipment: Personnel must wear appropriate safety gear, including hard hats, safety glasses, dust masks, and protective clothing.

 

2.Safety During Elevated Work: When performing work at heights, secure safety harnesses. Install fall protection nets or safety barriers.

 

3.Electrical Safety: Verify that the power supply is disconnected. Hang warning signs to prevent accidental operation.

 

4.Lifting Safety: During lifting operations, strictly follow lifting procedures. Ensure equipment stability to prevent dropped loads.

 

5.Emergency Response Measures: Develop an emergency response plan. Familiarize staff with evacuation routes and first aid measures. Ensure swift action during emergencies.

 

IV. Conclusion

Replacing the rollers and liners in a cement plant’s vertical mill is complex yet crucial. This task requires careful preparation and strict adherence to safety. This plan outlines project preparation, replacement steps, and safety considerations. It ensures the replacement process is efficient, safe, and smooth. Ultimately, it supports the stable operation of the cement production line.

If you have any needs or questions regarding cement machinery and equipment, please feel free to contact Darko. We are committed to providing professional products and solutions to support the efficient operation of your production line.

The cement production process continually seeks innovation and optimization. The introduction of a 7-stage cement kiln preheater raises important questions. What does this change mean? What opportunities and challenges will it bring to cement enterprises?

I. Advantages of the 7-Stage Cement Kiln Preheater

(A) Significant Energy Savings

The 7-stage cement kiln preheater increases the overall height from about 105 meters in a 5-stage system to 135 meters. This height increase leads to improved energy efficiency. The first-stage outlet temperature in a 5-stage preheater typically ranges from 310-330°C. In contrast, a 7-stage preheater can lower this temperature to 180-200°C. This adjustment reduces standard coal consumption from 98-102 kg to below 90 kg. For cement companies with high coal costs, this represents a valuable cost-saving measure. Additionally, using less coal lowers carbon emissions, helping companies meet future environmental standards.

(B) Improved Separation Efficiency

The 7-stage cement kiln preheater also shows better separation efficiency compared to the 6-stage system. In a 5-stage cyclone preheater, the first-stage separation efficiency is around 92%, reaching only 95% at best. This inefficiency leads to significant raw material loss. In contrast, the 6-stage system has a specific material consumption of about 1.55 to 1.58. The 7-stage preheater can improve this to a consumption of 1.49 to 1.52. Higher separation efficiency reduces energy consumption and boosts overall production efficiency.

(C) Support for Alternative Fuel Combustion and Ultra-Low Emissions

  • Optimized Alternative Fuel Combustion: The additional stage in the preheater allows for better combustion of alternative fuels. This improvement ensures that these fuels burn more completely, maximizing energy use. It also lessens the impact on SCR and baghouse equipment, extending their lifespan.

  • Enhanced Ultra-Low Emission Efficiency: The high collection efficiency of the 7-stage preheater positively affects SCR systems. Stable and low-dust concentration flue gas enters the SCR system, improving catalyst efficiency. This helps cement companies achieve and maintain ultra-low emission targets, complying with stricter environmental regulations.

(D) Advantages of Low Pressure Drop Design (New Production Lines)

New production lines using 6-stage or 7-stage cement kiln preheaters benefit from a low pressure drop design. The redesigned pre-decomposition system minimizes resistance. Each stage's pressure drop can be controlled at 600-800 Pa. When the production line reaches its designed feed rate, the first-stage outlet pressure drop stays below 5500 Pa. Even with a 20% overproduction, the pressure drop can remain below 6500 Pa. Lower pressure drops reduce energy consumption of high-temperature fans and lower long-term operating costs.

(E) Benefits from the Elimination of the Humidification Tower

The lower outlet temperature of the 7-stage preheater allows for the removal of the humidification tower. This change simplifies the process and eliminates the need for water spraying operations. When the preheating boiler is not running, operators can manage the dust collector's temperature effectively. This reduction in equipment decreases corrosion risks and improves system reliability.

Two pictures from a cement plant showing the working scene of a cement kiln preheater.

II. Challenges of the 7-Stage Cement Kiln Preheater

(A) Increased Construction Costs and Difficulty

Upgrading from a 5-stage to a 7-stage preheater raises investment costs. The higher frame and equipment heights complicate installation. This complexity requires more resources for equipment hoisting and precise installation, leading to longer project timelines and increased financial pressure.

(B) Impact on Raw Material Drying

The lower first-stage temperature means the kiln tail preheating boiler has an inlet temperature of about 200°C and an outlet temperature as low as 120°C. If raw materials have high moisture content, the mill may struggle to achieve production targets. To meet drying needs, companies may need to increase the load on high-temperature fans, raising energy consumption and affecting production stability.

(C) Reduced Waste Heat Power Generation

The lower kiln tail flue gas temperature leads to a decrease in waste heat power generation. The temperature drops from 35-40°C in a 5-stage system to 22-24°C per ton of clinker in a 7-stage system. While the 7-stage preheater brings energy savings, the reduced waste heat power generation means lower returns on energy recovery. Companies must optimize their energy management strategies to find new energy sources.

(D) Challenges in Controlling Flue Gas Temperature

To meet environmental requirements, bag dust collection is used at the kiln head and tail. If the waste heat boiler cannot run simultaneously, the maximum daily output of a 6-stage kiln system can reach only 60-70% of its designed capacity. Even with adjustments like small drafts or thicker layers, flue gas temperatures may exceed limits, risking damage to bag filters and increasing maintenance costs.

(E) High Costs for Upgrading Old Production Lines

Existing cement kilns face high retrofitting costs. Each stage of an old production line typically experiences a pressure drop of about 1200 Pa. Upgrading to a 7-stage preheater requires modifications to achieve low pressure drop design. If companies add a stage without upgrading the dust collector, system resistance will increase, causing operational costs to soar.

III. Conclusion and Outlook

In summary, the 7-stage cement kiln preheater offers significant advantages in reducing energy consumption, enhancing separation efficiency, supporting alternative fuel applications, and achieving ultra-low emissions. However, it also presents challenges, including high construction costs and impacts on raw material drying and waste heat power generation.

 

For new production lines, adopting the low pressure drop design of 6-stage or 7-stage preheaters is wise. This choice allows companies to benefit from technological advancements while avoiding complications and cost increases. For existing production line enterprises considering an upgrade, a thorough assessment of production conditions, energy costs, environmental requirements, and budgets is essential for informed decisions.

 

As the cement industry advances and faces stricter environmental requirements, the 7-stage preheater is likely to achieve further breakthroughs.

At Darko, we are dedicated to providing innovative solutions tailored to your needs. If you have questions or require assistance with our products, please contact us. We can offer customized solutions to support your transition to more efficient and sustainable operations. Let’s work together to lead the cement industry into a greener, smarter, and more efficient future.

System Problems

China Huaxing has a combined open-circuit grinding system composed of a roller press, a dispersion classifier, and a cement ball mill:

  • Roller Press: HFCG160-140, diameter Φ1600 mm, width Φ1400 mm, rotating speed 18.75 r/min, design capacity 670–780 t/h.
  • Dispersion Classifier: Model SF650/160, design capacity 700–850 t/h.
  • Ball Mill: Φ4.2 m × 13 m two-bin mill, rotating speed 15.8 r/min, design capacity 150 t/h.

Main Issues Encountered

  • Metal Impurities: Introduced by material and equipment wear, causing frequent vibrations in the roller press and leading to spalling of the roller surfaces. The accumulation of metal impurities creates a buffering effect on the grinding, resulting in accelerated wear and deteriorating efficiency.

  • Low Efficiency of the Dispersion Classifier: Rapid wear and difficulty in grade control make it challenging to regulate the fineness of entering material. High moisture content can lead to clogging of sieve plates, preventing normal production.

  • Clogging Issues: Coarse fineness of entering material clogs the discharge grate's gaps, causing poor ventilation, material return at the mill head, environmental contamination, and reduced production capacity.

Retrofitting Program

1. Installation of Iron Removers and Metal Separators

  1. Increase iron removal testing for raw materials upon delivery. Install iron removers at each raw material feeding point, lowering the height between the iron remover and the material surface to enhance the iron removal effect.
  2. Install a metal separator to detect any metal not removed by the iron remover. Detected metal will be separated using a vibrating screen at the conveyor belt head for manual retrieval.

  3. Install a pipeline iron remover at the coarse powder discharge chute of the V-type classifier to ensure continuous removal of iron slag from the system.If you require any further information, please contact us.

2.Retrofitting of Roller Press & Breaking Classifier

2.1 Upgrading the Dispersing Classifier to a Two-Stage Small V-Type Powder Classifier

The original dispersion classifier has the following deficiencies:

 

  1. Low Classification Efficiency: Approximately 22%, resulting in coarse fineness. Sieve residue reaches 55% with particles up to 8 mm.
  2. High Maintenance Costs: The mechanical classification leads to increased costs.
  3. Poor Material Adaptability: Reduced classification ability with high moisture content and inadequate handling of material changes.

 

The system has been upgraded to a two-stage small V-type classifier. The material pressed by the roller press is conveyed to the first-stage classifier. Qualified material is sent to the ball mill, while return material enters the second-stage classifier for further sorting.

 

Advantages of this System:

 

  • Low energy consumption (total installed power of 200 kW)
  • Low investment
  • High classification efficiency (87%)

 

2.2 Upgrade of Material Stabilization and Pressure Stabilization for the Roller Press

The HFCG160-140 roller press has the following issues:

  1. Manual feeding device adjustment lacks central control.
  2. Poor performance with a low fine powder content (about 15%) and low working current.
  3. Constant pressure control system does not auto-adjust roller gap based on material feed conditions.

 

To solve the above defects, Darko upgraded the roller press system through a number of new technologies. The upgrade plan includes:

  • Modification of Feeding Device: A new multi-directional feeding device ensures stable roller operation.
  • Addition of a Roller Gap Adjustment Device: Introduces a constant pressure and roller gap control system, minimizing variations.
  • Replacement of Hydraulic System: Upgraded to include damping and stroke adjustment valves for improved stability and performance.

 

3.Modification of Ball Mills

Transforming the Feeding Device: The new device incorporates a five-blade spiral feeder and a deceleration buffer plate to enhance grinding efficiency.
Lightweight and Transformation of Lining Plates: New lighter lining plates improve ball-carrying capacity and reduce power consumption.
Using Anti-Clogging Grates: Modifications to sieve holes increase material passage capacity and prevent over-grinding.

 

4.Upgrade of the Dust Collector Ash Return Discharge Point

The specific surface area of the ash returned from the dust collector is between 365 and 410 m²/kg. The discharge point of the original dust collector has been changed to directly channel the ash into the ball mill, reducing the load and amount of material entering the mill.

 

Vertical roller mills (VRMs) have become essential equipment in the cement industry. They are widely used for drying and grinding processes. These machines grind cement raw materials, coal, clinker, and other industrial materials, such as steel slag and ceramics.

 

Two combined scenes of a vertical roller mill, showcasing its operational setup and components in a cement production environment.

The Significance of Vertical Roller Mills

Vertical roller mills offer unique advantages in their operation, grinding mechanisms, mechanical structures, and process performance. As a result, they attract more attention in the global cement industry. With the introduction of kiln outside decomposition technology, many countries now use VRMs to grind cement raw materials and clinker. Here are the key advantages of vertical roller mills compared to traditional cement ball mills:

1. High Energy Efficiency

Vertical roller mills reduce energy consumption significantly. They typically use 20% to 30% less energy than ball mills. This efficiency makes them a more sustainable choice for cement production.

 

2. Compact Footprint

Vertical roller mills require less floor space. Their compact layout integrates the classifier within the mill, eliminating the need for separate classifiers and elevators. This design can reduce building area by 30% for the same production capacity.

 

3. Strong Drying Capacity

Vertical roller mills effectively dry materials with a moisture content of 12% to 15%. They achieve this by using hot gas for material transport. This capability allows producers to eliminate the need for a separate drying system and further optimize production processes.

 

4. Long Lifespan of Wear Parts

The design of vertical roller mills minimizes direct metal contact. This reduces wear and increases operational rates. As a result, the lifespan of critical wear components extends, lowering maintenance costs.

 

5. Large Feed Size

Vertical roller mills handle larger feed sizes, typically between 80 to 120 mm. Some large-scale mills can accommodate up to 200 mm. This feature enhances crushing capacity and simplifies the overall process compared to ball mills, which usually require smaller feed sizes.

 

6. Lower Noise Levels

Vertical roller mills operate at noise levels about 10 dB lower than ball mills. This reduction improves the working environment. Additionally, they make it easier to monitor and control product fineness and composition. Maintenance is also simpler.

 

Layout Options

Vertical roller mills usually offer two layout options based on the positioning of the humidification tower and dust collector: a three-fan system and a dual-fan system. They use a cyclone dust collector for product collection, which reduces the system's negative pressure and the volume of gas passing through the dust collector. The exhaust gas can directly enter the dust collector, which may be an electrostatic precipitator or a bag filter. This setup reduces the number of equipment units and simplifies the overall layout.

 

Common Issues

Wear of Grinding Rollers

During operation, the grinding rollers and wear plates face various forces, such as roller pressure and material friction. When wear increases the gaps in the fit, it can lead to severe impacts, causing cracks or breakage. This damage affects equipment performance. Traditional repair methods often fail and take too much time. Therefore, many developed countries, including the U.S. and Europe, use high-performance composite materials for on-site repairs. This approach effectively extends equipment lifespan, improves productivity, and minimizes downtime.

 

Bearing Chamber Wear

The assembly of bearings in vertical roller mills is strict. Typically, operators cool the bearings to low temperatures for precise assembly. If gaps appear between the bearings and their chambers, it can cause overheating and even seizure. Traditional repair methods, such as welding and coating, risk damaging the bearing material due to thermal stress. High polymer composite materials, like those from our brand Darko, offer the necessary strength and flexibility. They absorb external impacts effectively, preventing further wear from gap enlargement.

 

Conclusion

Vertical roller mills play a crucial role in modern cement production. Their efficiency, energy savings, and compact design make them increasingly popular. If you have any questions or needs regarding vertical roller mills, please feel free to contact us. Our team at Darko is here to help you with advanced solutions for your cement production challenges.

The star discharge valve is an unloading device designed for discharge points that operate under negative pressure. It conveys materials using a rotating rotor. This design provides a sealing effect that prevents air from being drawn in during pneumatic conveying, ensuring normal discharge.

 

Features of Star Discharge Valve

  • Compact Structure and Attractive Design: The design is user-friendly and convenient.

 

  • Smooth Operation and Low Noise: It operates quietly, enhancing user comfort.

 

  • Superior High-Temperature and Lubrication Performance: The bearings and gearboxes are positioned away from the housing, improving performance under high temperatures.

 

  • Custom Design: We can create designs tailored to your specific requirements.

 

  • Lubrication Maintenance: Each valve is filled with special lubricants before leaving the factory. Regular checks for lubrication are recommended.

 

Star discharge valves are commonly used in pneumatic conveying systems. They supply materials uniformly and continuously to the conveying pipe. This ensures stability for gases and solids within the pneumatic transport system. Additionally, they isolate pressure in the valve's upper and lower sections, achieving a locking effect. Therefore, the star discharge valve is essential for pneumatic conveying systems.

 

Star ash discharge valve in operation, illustrating the mechanism of controlled ash discharge in a power plant setting

Applications of Star Discharge Valve

Star discharge valves serve as unloading devices in material collection systems, particularly for silos. They rank among the most advanced unloading devices available today. These valves are commonly used in dust removal systems and are especially suitable for dust and small particle materials. Industries such as environmental protection, metallurgy, chemicals, food, cement, road construction, and drying equipment favor star discharge valves for various projects.

 

 

Selection Guide for Star Discharge Valves

Choosing the right star discharge valve involves several key steps:

 

1. Define the Usage Location

Determine if the valve will be used indoors or outdoors. This choice influences protective measures.

 

2. Determine the Purpose of Use

Clarify if the valve will discharge materials in a metered, full-volume, or air-locking manner. This helps select the appropriate model.

 

3. Specify the Material Flow Rate

Understand the valve's hourly flow rate. Specify whether the discharge is metered or variable to select the right capacity.

 

4. Define the Conveying Method

Classify the type of conveying: pneumatic or gravity flow. Clarifying this helps in selecting the correct valve.

 

5. Understand the Conveyed Material

Know the material characteristics and the pressure difference between the inlet and outlet flanges of the blower. This knowledge aids in determining the valve's material and structure.

 

6. Analyze Material Properties

Consider properties like material name, particle size, true density, bulk density, temperature, repose angle, moisture content, and viscosity. These factors will influence the valve's selection and configuration.

 

7. Consider Special Requirements

If you need an acceleration chamber or exhaust chamber, specify the models required. Also, consider the manufacturer of the reducer motor and the protection level.

 

8. Material Selection

Different materials have specific requirements. For example, food processing and pharmaceutical industries often require stainless steel star discharge valves due to their corrosion resistance and durability at high temperatures.

 

9. Safety Performance

Ensure safety and ease of operation by selecting reliable brands and models known for stability.

 

By following these steps, you can effectively choose a star discharge valve that meets your needs, ensuring stable operation and high performance in your production process.

 

 

Conclusion

In summary, selecting the right star discharge valve is crucial for efficient operation in your material handling systems. If you seek high-quality valves, Darko offers a range of reliable options tailored to your needs. For any inquiries or to discuss your specific requirements, please contact us. We are here to help!

High-temperature dust filter bags play a crucial role in industrial dust collection systems. Their lifespan directly affects both operational efficiency and maintenance costs. Therefore, extending the lifespan of these bags is a key focus for many customers. This article outlines several strategies to help you achieve this goal.

Choose the Right Material

Selecting the appropriate material is vital. When choosing high-temperature dust filter bags, consider your specific working conditions. For flue gases that are hot, humid, and corrosive, opt for materials like fluoropolymer or P84. These materials resist high temperatures and corrosion. For general industrial dust, polyester needle felt bags work well.

Assess Operating Conditions

1. Nature of Flue Gas

The composition of flue gas significantly impacts bag durability. If the gas contains high levels of acidic or corrosive substances, it will weaken the bags. Industries like chemical and metallurgy often face this issue, leading to shorter bag lifespans.

2. Temperature

High temperatures can cause severe damage to filter bags. Each material has a specific temperature limit. If you exceed this limit, the bags will age quickly and fail. Therefore, monitor temperatures closely to protect your investment.

3. Characteristics of Dust

The properties of dust also matter. Sharp or hard particles can wear down the bags. Additionally, sticky dust can accumulate, blocking airflow and increasing resistance. This buildup can lead to premature damage.

High-efficiency dust collector filter bag designed for industrial applications, ensuring optimal dust capture and air quality.

Proper Installation and Use

Correct installation and usage are essential for maximizing bag life. Follow the manufacturer’s instructions carefully. Here are some key tips:

 

  • Ensure Proper Fit: During installation, make sure the bags fit the flower plate holes precisely. This prevents wear and air leaks.

 

  • Conduct Regular Inspections: Frequently check the equipment’s operation. Look for any signs of wear or clogging. Cleaning the bags regularly helps maintain airflow.

 

  • Control Flue Gas Temperature: Keep a close eye on gas temperatures. Avoid excessive heat, which can harm the bags.

 

  • Choose the Right Filtration Velocity: Select a suitable filtration speed. High speeds can cause unnecessary wear on the bags.

 

Additional Tips to Extend Bag Lifespan

  • Avoid Mixing Bags: Do not mix old and new bags. Different wear patterns can disrupt system performance.

 

  • Monitor for Aging: Regularly check for signs of aging. High temperatures and exposure to corrosive substances can degrade the bags. Replace any that show significant wear.

 

  • Adjust Tightness: Ensure bags are neither too loose nor too tight. Loose bags can collect dust, while tight ones may tear.

 

  • Clean and Replace Bags: When replacing bags, use compressed air to blow out dust. Check for holes and repair if needed. If bags are heavily soiled, rinse them with water and let them dry before using them again.

 

  • Address Clogging Promptly: Clogging increases resistance, indicated by pressure gauge readings. To fix clogs, consider these steps:

    • Temporarily increase cleaning frequency to remove blockages.
    • Replace some or all bags as needed.
    • Adjust installation or operating conditions to prevent future issues.

Types of Dust Filter Bags

Dust filter bags come in various designs. You can find pulse-jet, shaking, and reverse-jet types. They also vary in shape, including round, flat, and envelope styles. Different designs cater to specific applications, allowing for flexibility based on your needs.

Conclusion

Extending the lifespan of high-temperature dust filter bags is essential for improving the efficiency of dust collection systems and reducing costs. By choosing the right materials, assessing operating conditions, ensuring proper installation, and conducting regular maintenance, you can significantly enhance the longevity of these bags. Use these strategies to protect your investment and maintain effective dust control in your operations.

 

At Darko, we specialize in high-quality dust filter solutions tailored to your industrial needs. For more information or to discuss your specific requirements, contact us today! Our team is ready to assist you in optimizing your dust collection systems and enhancing performance.

In cement production, the roller press is a key piece of equipment, and its operational stability directly affects production efficiency and product quality. Below are specific cases and experience sharing regarding fault handling from T Company, J Company, and S Company. If you encounter similar issues during equipment operation, feel free to contact us at Darko. As a professional manufacturer and supplier of cement equipment, we are dedicated to providing you with high-quality equipment and services.

High-efficiency roller press used in cement production for material compaction and grinding.

Cement Plant A Abnormal Situation Description

Fault Phenomenon

Cement Plant A uses a vertical feeding pipe between the roller press and the weighing silo. However, this pipe is too short. As a result, the roller press experiences low working pressure and poor extrusion capability. Consequently, the feed material has high screening residue and low fine powder content. This situation leads to low system yield and high grinding energy consumption.

 

System Configuration

  • Roller Press: 120-50 roller press (material throughput 165t/h, main motor power 250kW, current 21A×2)
  • Dispersing and Classifying Machine: 550/120 (processing capacity 140—175t/h, motor power 45kW+30kW)
  • Tube Mill: Φ3.2×13m three-chamber open circuit tube mill (main motor power 1600kW, grinding media loading 127t)
  • Dust Collection Fan: Comprises an open circuit combined grinding system

 

Results

The system produces P.O42.5 grade cement with a finished specific surface area of at least 380±10m²/kg. It achieves a yield of 65t/h while consuming 35kWh/t of energy. However, the R80μm residue of the feed material reaches 78.7%, resulting in only 21.3% of the material being fine powder. This leads to a high content of coarse particles in the finished cement.

 

Technical Diagnosis Analysis

The vertical feeding pipe height between the roller press and the weighing silo is less than 1.2m, causing low material pressure in the pipe, requiring frequent adjustment of the rod valve. The weighing silo frequently experiences segregation or material collapse, and there is significant dust in the production area. The working pressure of the roller press is only 6.0—6.5MPa, which directly affects the extrusion effect of the material.

 

Technical Measures and Effects

During the annual overhaul, the height of the elevator and weighing silo was increased, raising the vertical feeding pipe height to 2.5m. The side plates of the roller press were repaired by overlay welding to reduce leakage. Maintaining the weighing silo's material level at 60%—70% eliminated segregation and material collapse. The working pressure of the roller press was adjusted to 7.2—7.5MPa, and the R80μm residue of the feed material was reduced to 49.8% (with the fine powder content reaching 50.2%). The system yield increased to 79t/h, and grinding energy consumption decreased to 26.4kWh/t. Annually, this modification can save 4.8 million kWh of electricity, resulting in an economic benefit of over 2.8 million RMB.

 

Cement Plant B Abnormal Situation Description

Fault Phenomenon

At Cement Plant B,operators face unstable feeding control to the roller press. This instability results in poor working capability. Consequently, the main motor produces insufficient output. As a result, the feed material contains low fine powder content. Ultimately, this situation leads to low yield and high grinding energy consumption.

 

Grinding System Configuration

  • Roller Press: 170-100 roller press (material throughput 620t/h, main motor power 900kW)
  • Classifier: Vx8820
  • Tube Mill: φ4.2×13m double-chamber tube mill (main motor power 3550kW)
  • Dust Collection Fan: Comprises a double closed-circuit combined grinding system

 

Results

The system produces P.O42.5 grade cement at a yield of 165t/h (finished fineness R45μm residue 9.0±1.0%), with grinding energy consumption reaching 44kWh/t.

 

Technical Diagnosis Analysis

The unstable feeding to the roller press results in poor extrusion capability and insufficient motor output, with the operating current only at 42%—45%. The specific surface area of the feed material is around 160m²/kg.

 

Technical Measures and Effects

A patent technology from a technology company, the "Lever-type Dual Feeding Device for Roller Press," was adopted to stabilize feeding control, increasing the main motor output to 72%—78%. Internal structural improvements ensured a higher content of finished material in the output. Ultimately, the system yield for P.O42.5 grade cement reached 210t/h, and grinding energy consumption decreased to 38.1kWh/t, achieving a 13.41% energy saving. After optimizing system power, production efficiency was significantly improved.

Cement Plant C Abnormal Situation Description

Fault Phenomenon

At Cement Plant C, both fly ash and desulfurized gypsum with small particle sizes enter the weighing silo together. The high moisture content of the desulfurized gypsum causes severe material adhesion on the silo walls, impacting the output of the roller press and the overall system yield.

 

Grinding System Configuration

  • Roller Press: 120-50 roller press (material throughput 165t/h, main motor power 250kW)
  • Dispersing and Classifying Machine: 550/120
  • Tube Mill: Φ3.2×13m three-chamber tube mill (main motor power 1600kW)
  • Dust Collection Fan: Comprises an open circuit combined grinding system

 

Results

The system produces P.O42.5 grade cement at a yield of 65t/h (finished specific surface area ≥ 360±10m²/kg), with grinding energy consumption of 33kWh/t. The R80μm residue of the feed material is more than 65% (with <80μm fine powder content around 35%).

 

Technical Diagnosis Analysis

The powdery materials affect the extrusion capability of the roller press, leading to low operating current. The weighing silo experiences severe material adhesion due to high moisture content, affecting the flow of material in the feeding pipe.

 

Technical Measures and Effects

Fly ash and desulfurized gypsum were switched to separate metering before direct feeding into the tube mill, and the adhesion on the walls of the weighing silo was cleaned to create stable material pressure. The roller press achieved over-saturated feeding, improving extrusion performance. The R80μm residue of the feed material was reduced to 55% (with <80μm fine powder content reaching 45%). The P.O42.5 cement yield increased to 75t/h, a rise of 15.38%; grinding energy consumption decreased to 30kWh/t, achieving a 9.1% energy saving.

 

Conclusion

The stable operation of the roller press is crucial for cement production. We can achieve this by monitoring equipment status and optimizing operational processes. Additionally, conducting regular maintenance helps us reduce faults effectively. This, in turn, improves production efficiency and enhances product quality. If you encounter any issues with cement equipment, please contact us. Darko, as a professional manufacturer and supplier of cement equipment, is committed to providing quality equipment and solutions. Together, we can drive progress in the industry.

dust explosions

Preventing dust explosions requires a multi-faceted approach. Dust explosions happen when dust concentrations reach a certain level, mix with air, and encounter an ignition source. Fine dust particles create a flammable mixture in the air. When ignited, they release a large amount of energy, leading to an explosion. Therefore, controlling dust concentration and cleaning promptly are crucial to preventing explosions.

 

Here are some key preventive measures:

Control Dust Concentration

  • Ensure Equipment Sealing: Make sure that all equipment, containers, and conveying systems are well-sealed to minimize dust leakage.

 

  • Improve Ventilation and Dust Removal: Install effective ventilation and dust removal systems. This will enhance dust extraction and reduce dust levels in the workshop. Darko's dust collectors provide high filtration efficiency and reliability to help companies manage dust effectively.

 

  • Manage Dust Accumulation and Cleaning: Keep the floors, walls, and ceilings of the workshop smooth and free of protrusions to make cleaning easier. Use explosion-proof vacuum cleaners for regular cleaning. Additionally, spray water to dampen dust when possible. Increasing air humidity to over 65% helps dust settle and absorbs heat from dust oxidation, which reduces static electricity risks.

 

Control Ignition Sources

  • Choose Equipment Wisely: When maintaining dust-laden equipment, it is essential to use tools that do not create sparks from impact or friction. Additionally, ensure that all electrical equipment meets explosion-proof standards. Furthermore, avoid installing machinery that generates static electricity or sparks, and implement static grounding measures to enhance safety.

 

  • Manage Open Flames: Designate areas with combustible dust as no-fire zones. Moreover, control the use of open flames strictly. Before welding in these areas, ensure that all materials are cleared from the equipment. Additionally, take steps to prevent slag from falling into machines or onto materials.

 

  • Install Spark Detection and Extinguishing Systems: In suitable workshops, it is important to install spark detection and fire extinguishing systems. Specifically, these systems can detect sparks in dust removal ducts or powder conveying pipes. In addition, they use water mist to extinguish sparks quickly and effectively.

 

Control Oxygen Content

In some cases, fill the grinder with inert gases like nitrogen or carbon dioxide. This lowers the oxygen content in the system and helps prevent dust explosions.

 

Implement Additional Measures

  • Handle Materials Properly: Screen, de-stone, and remove metals from crushed materials to prevent sparks from impurities entering the crusher.

 

  • Control Temperature: Ensure that the surface temperature of heating devices and high-temperature pipes does not exceed the ignition temperature of the dust cloud.

 

  • Conduct Regular Inspections and Maintenance: Regularly check electrical equipment to prevent aging or short circuits that can create ignition sources.

 

  • Provide Personnel Training: Strengthen safety education for staff. Increase their awareness of dust explosion hazards and teach them basic emergency response skills.

 

Develop an Emergency Plan

Create an emergency plan for dust explosions. This plan should include steps for emergency evacuation, initial fire-fighting, and personnel rescue. It ensures a timely and effective response in the event of a dust explosion.

By implementing these measures, companies can significantly lower the risk of dust explosions while protecting their personnel and property. At Darko, we are committed to providing efficient dust management solutions. Our products help companies effectively control dust and maintain safe operations. If your company has any questions about dust collection systems, please don’t hesitate to reach out to us.

In today’s rapidly advancing technological landscape, the pharmaceutical industry encounters unique challenges and opportunities. People demand better health and expect higher quality drugs. Additionally, stricter environmental regulations require the industry to prioritize environmental protection during production. Therefore, cartridge dust collectors have emerged as essential green guardians in this sector. Their efficiency and eco-friendliness make them crucial for meeting industry needs.

Basic Principles and Features of Cartridge Dust Collectors

A cartridge dust collector is an advanced dust removal device. It works by filtering dust particles from the air through cartridges. This process purifies the air. The main features include:

 

  • High Dust Removal Efficiency: These collectors use advanced filtering materials. They efficiently capture fine dust particles from the air, ensuring a clean production environment.

  • Energy Saving and Eco-Friendliness: Cartridge dust collectors consume low energy during operation. They can also recover some dust resources for reuse, aligning with modern environmental ideals.

  • Easy Maintenance: Their well-designed structure makes them easy to disassemble and clean. This feature reduces maintenance costs and enhances reliability and lifespan.

 

Off-line pulse jet baghouse filters in an industrial setting, showcasing their chambered design and dust collection capabilities.

Applications of Cartridge Dust Collector in the Pharmaceutical Industry

Cartridge dust collectors are widely used in the pharmaceutical industry. They cover various processes, such as active pharmaceutical ingredient (API) production, solid dosage form production, and liquid dosage form production. Here are some specific examples:

 

  • API Production: This process generates a large amount of dust and harmful gases. Cartridge dust collectors capture these pollutants effectively. They prevent harm to the production environment and protect employee health. Additionally, they recover valuable dust resources, improving raw material utilization.

  • Solid Dosage Form Production: In the production of solid dosage forms like tablets and capsules, cartridge dust collectors are installed on production lines. They effectively capture generated dust, ensuring a clean production environment and maintaining product quality.

  • Liquid Dosage Form Production: Although liquid dosage forms produce less dust, some operations, like mixing and filling, may still generate small amounts. Cartridge dust collectors play a crucial role in maintaining cleanliness and ensuring employee health in these processes.

 

Development Trends and Challenges of Cartridge Dust Collector in the Pharmaceutical Industry

As the pharmaceutical industry evolves, cartridge dust collectors will display several trends:

 

  • Intelligent Development: With advancements in IoT and big data, these collectors will become smarter. They will use remote monitoring and data analysis to improve operational efficiency and reliability.

  • Increased Efficiency and Energy Savings: Future cartridge dust collectors will focus more on efficiency and energy savings. They will use advanced filtering materials and optimize their designs to reduce energy consumption and operational costs.

  • Environmental Protection and Resource Recovery: These collectors will emphasize environmental protection and resource recovery. They will recycle dust resources, helping conserve resources and protect the environment.

 

However, the application of cartridge dust collectors also faces challenges. The diversity of dust characteristics and the complexity of production environments require continuous research and development. We must improve technologies to meet the industry’s evolving needs.

 

Importance of Cartridge Dust Collector in the Pharmaceutical Industry

The use of cartridge dust collectors improves the cleanliness of the production environment and enhances product quality. They also promote sustainable development in the pharmaceutical industry. Their significance includes:

 

  • Protecting Employee Health: By capturing dust and harmful gases, these collectors prevent health hazards for employees. They create a safe and healthy working environment.

  • Improving Product Quality: By ensuring cleanliness in the production environment, cartridge dust collectors enhance product quality and stability. This support is crucial for the industry's development.

  • Promoting Environmental Protection: Through dust recovery and reuse, these collectors contribute to resource conservation and environmental protection. They play an important role in the sustainable development of the pharmaceutical industry.

 

Conclusion

Cartridge dust collectors serve as green guardians in the pharmaceutical industry. They provide essential support for development. Their efficiency and environmental benefits are crucial. In the future, as technology advances and awareness of environmental issues increases, these collectors will play an even larger role in the industry. Darko is committed to advancing and innovating cartridge dust collector technology. We aim to contribute to the sustainable development of the pharmaceutical sector. If you have any questions about our dust collectors or services, please feel free to contact us. We look forward to working with you.

11月 2024

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